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Highly crystalline macroporous β-MnO2: Hydrothermal synthesis and application in lithium battery

2010; Elsevier BV; Volume: 55; Issue: 17 Linguagem: Inglês

10.1016/j.electacta.2010.03.090

1873-3859

Xingkang Huang, Dongping Lv, Qingshun Zhang, Haitao Chang, Jianlong Gan, Yong Yang,

Advanced Battery Materials and Technologies

A highly crystalline macroporous β-MnO2 was hydrothermally synthesized using stoichiometric reaction between KMnO4 and MnCl2. The as-prepared material has a pore size of ca. 400 nm and a shell thickness of 300–500 nm. The formation of the macroporous morphology is related to self-assembling from nanowires of α-MnO2, and could be obtained at high reactant concentrations (e.g., 0.8 M KMnO4) but not at low ones (e.g., below 0.04 M KMnO4). Compared to conventional bulk β-MnO2 processing very low capacity, our macroporous material exhibits good electrochemical activity, e.g., obtaining an initial discharge capacity of 251 mAh g−1 and sustaining as ca. 165 mAh g−1 at 10 mA g−1. The electrochemical activity of the as-prepared β-MnO2 is related to its macroporous morphology and small shell thickness; the former leads to that electrolyte can flood pore of the material and its inner surface is available for lithium ion diffusion, while the latter helps to release the stress from phase transformation during the initial discharging. The X-ray diffraction characterizations of the macroporous β-MnO2 electrodes suggest that, upon initial discharging, such a β-MnO2 will be irreversibly transformed to an orthorhombic LixMnO2 and then cycled within the new developed phase in the subsequent lithium insertion/extraction processes.